A system and method for depositing a coating may comprise a coating chemical reactor, surface activation component, and a deposition component. A target surface may be prepared for deposition with the surface activation component. The coating chemical reactor may comprise a coating chemical dispenser and a coating chemical verifier that prepares the coating chemical for deposition. The coating chemical verifier may utilize an optical excitation source and at least one optical detector, wherein chemical substances are identified by unique signatures composed of binary code. The coating chemical may be received by the deposition component to depositing the coating chemical on the target surface.

A system and method for depositing a coating may comprise a coating chemical reactor, surface activation component, and a deposition component. A target surface may be prepared for deposition with the surface activation component. The coating chemical reactor may comprise a coating chemical dispenser and a coating chemical verifier that prepares the coating chemical for deposition. The coating chemical verifier may utilize an optical excitation source and at least one optical detector, wherein chemical substances are identified by unique signatures composed of binary code. The coating chemical may be received by the deposition component to depositing the coating chemical on the target surface.

A damage process for a textile product may include, but is not limited to, irradiating a laser beam onto a surface region of a textile product which is dyed, to burn the surface region, exposing the textile product to an ozone gas; and agitating the textile product together with at least one of: pieces of one or more solid materials having uneven surfaces and one or more abrasives of artificial fibers to allow the surface region to be shaved by the at least one of: the pieces of one or more solid materials and the one or more abrasives of artificial fibers. One or more subsequent processes can be carried out, without dipping the textile product into water or a liquid of chemicals, after agitating the textile product and until softening the textile product.

A damage process for a textile product may include, but is not limited to, irradiating a laser beam onto a surface region of a textile product which is dyed, to burn the surface region, exposing the textile product to an ozone gas; and agitating the textile product together with at least one of: pieces of one or more solid materials having uneven surfaces and one or more abrasives of artificial fibers to allow the surface region to be shaved by the at least one of: the pieces of one or more solid materials and the one or more abrasives of artificial fibers. One or more subsequent processes can be carried out, without dipping the textile product into water or a liquid of chemicals, after agitating the textile product and until softening the textile product.

A functional substance adsorption device for fibers including: a casing having a space formed therein and an opening and closing door located on the front surface thereof; a drum rotatably disposed inside the casing and having a space formed therein to put the fibers therein and a plurality of fine through holes formed thereon; a driving part disposed on one side of the casing to rotate the drum; and a fine particle supply part comprising a fine particle supply hose communicating with the outer periphery of the casing, a vaporization tank connected to one side of the fine particle supply hose, a pneumatic ultrasound generator disposed inside the vaporization tank to vaporize an antimicrobial agent, and an air compressor for supplying pneumatic pressure to the pneumatic ultrasound generator.

A functional substance adsorption device for fibers including: a casing having a space formed therein and an opening and closing door located on the front surface thereof; a drum rotatably disposed inside the casing and having a space formed therein to put the fibers therein and a plurality of fine through holes formed thereon; a driving part disposed on one side of the casing to rotate the drum; and a fine particle supply part comprising a fine particle supply hose communicating with the outer periphery of the casing, a vaporization tank connected to one side of the fine particle supply hose, a pneumatic ultrasound generator disposed inside the vaporization tank to vaporize an antimicrobial agent, and an air compressor for supplying pneumatic pressure to the pneumatic ultrasound generator.

A functional substance adsorption device for fibers including: a casing having a space formed therein and an opening and closing door located on the front surface thereof; a drum rotatably disposed inside the casing and having a space formed therein to put the fibers therein and a plurality of fine through holes formed thereon; a driving part disposed on one side of the casing to rotate the drum; and a fine particle supply part comprising a fine particle supply hose communicating with the outer periphery of the casing, a vaporization tank connected to one side of the fine particle supply hose, a pneumatic ultrasound generator disposed inside the vaporization tank to vaporize an antimicrobial agent, and an air compressor for supplying pneumatic pressure to the pneumatic ultrasound generator.

A damage process for a textile product may include, but is not limited to, irradiating a laser beam onto a surface region of a textile product which is dyed, to burn the surface region, exposing the textile product to an ozone gas; and agitating the textile product together with at least one of: pieces of one or more solid materials having uneven surfaces and one or more abrasives of artificial fibers to allow the surface region to be shaved by the at least one of: the pieces of one or more solid materials and the one or more abrasives of artificial fibers. One or more subsequent processes can be carried out, without dipping the textile product into water or a liquid of chemicals, after agitating the textile product and until softening the textile product.

A damage process for a textile product may include, but is not limited to, irradiating a laser beam onto a surface region of a textile product which is dyed, to burn the surface region, exposing the textile product to an ozone gas; and agitating the textile product together with at least one of: pieces of one or more solid materials having uneven surfaces and one or more abrasives of artificial fibers to allow the surface region to be shaved by the at least one of: the pieces of one or more solid materials and the one or more abrasives of artificial fibers. One or more subsequent processes can be carried out, without dipping the textile product into water or a liquid of chemicals, after agitating the textile product and until softening the textile product.

Methods and systems are described for continuously densifying at least one nanofiber sheet using heat and an applied force that can include both compressive and tensile components. Nanofiber sheets densified using these techniques have a more uniform and more highly aligned microstructure than nanofiber sheets densified using a solvent alone. As a result, the nanofiber sheets of the present disclosure have, for example, higher tensile strength and better electrical conductivity than nanofiber sheets densified using other techniques.